AT16826U1 - CO2 air filter - Google Patents

Abstract

The invention relates to CO2 air filters 1. for installation in ventilation ducts, primarily in circulating air devices based on soda lime, consisting of sodium hydroxide, calcium hydroxide, water and ethyl violet as CO2 sorbing material, the proportion of sodium hydroxide not exceeding 4%. 2. With a reducing, electrostatic pre-filter for fine dust and fine dust to keep the surface of the CO2 sorbent material clean.

Description

description

THE INVENTION CONCERNS CO »2 AIR FILTERS

STATE OF THE ART

[0001] CO »air filters have long been known from submarines and bunker systems in military technology. Such filters have also established themselves in anesthesia devices in medical technology. Devices and systems have also been around for a long time but have not been able to establish themselves in the area of ventilation, especially living space ventilation and circulating air devices. For example, DE 19842632 describes solutions which are intended to limit the CO »content in vehicle interiors using a CO» filter based on soda lime. KR 1020160036257 shows a circulating air device for living areas which reduces CO »using soda lime. The structure of the associated filter is described in KR 1021040112111 and is based on a CO> »absorbing material and several layers of filter mats and dust filters. Various substances are also used for absorption. In DE 19842632, besides soda lime, the composition of which is not specified, lithium hydroxide and potassium hyperoxide are also described.

DISADVANTAGE

Disadvantages of these inventions are, on the one hand, the rapid contamination of the surface-active substances and their pores by fine dust <10 μm and the settling of the filler material in the filter housing that takes place in practice due to vibration and the associated uneven density over the surface against which the flow occurs. In addition, soda lime mixtures are used that have an insufficient service life, e.g. Lithium hydroxide or potassium hyperoxide. Other mixtures for soda lime, e.g. EP 0736403, are sensitive to excessively high humidity, which requires additional measures for air dehumidification in the device.

OBJECT OF THE INVENTION

The object is to provide a device which overcomes the disadvantages of the prior art.

In particular, the compression and settlement of chemically active sorbents based on bulk material and the premature contamination of the active surfaces of all materials used is to be reduced.

SOLUTION OF THE TASK

According to the invention, the object is achieved through the use of a mixture of sodium hydroxide, calcium hydroxide, ethyl violet and water as soda lime, the proportion of sodium hydroxide not exceeding 4% as CO2 sorbing material in a filter housing with internal chambers which, due to their size, cause a settlement of the Prevent material of more than 2.5% and dust filters sealingly upstream and downstream, which prevent dust from the sorbent material from escaping into the breathing air, and a fine dust separation based on the electrostatic principle on the upstream side.

[0006] Advantageous embodiments of the invention are given in the dependent claims.

A first aspect of the invention relates to the filter cassette with the sorbent material. A material is used that is stable to sodium hydroxide and can be disposed of in an environmentally friendly manner. A material is preferably used which can also be easily incinerated. The inside of the filter cassette has air-permeable chamber structures in the direction of flow, which prevent the filling material from settling or compressing by more than 2.5%. These chamber structures can on the one hand consist of solid material, but also in the form of flexible material that prevents the filler from sagging. Fabrics, but also air-permeable foils and plastics, can be used as flexible materials.

The inflow and outflow side is secured against the unwanted escape of fine dust from the filling material with a flexible or rigid, air-permeable dust filter mat sealing the filter frame.

In addition, this dust filter mat can be secured by an air-permeable rigid filter cover. This filter cover also has the advantage that the filler material also remains stable in the chambers in the third dimension, i.e. in the air direction.

According to the invention, the filter comprises a fine dust separator on the inflow side for dusts <10 μm. This fine dust separation is based on the electrostatic principle. The incoming air is electrostatically charged by means of a permanent or pulsating electrical discharge using a spray electrode. The dust particles charged in the process are then deposited in front of the filter cassette on grounded or oppositely polarized metallic components. The electrical charging of the air can be positive or negative.

In another advantageous embodiment, the fine dust filter itself is used on the inflow side to separate electrically charged fine dust.

Another aspect of the invention relates to the installation of this filter and its upstream fine dust separation in circulating air ventilation devices.

According to the invention, this filter is installed in a ventilation duct located in the device circumferentially sealing and replaceable before or after the fan and other built-in parts through which air flows. Since the room to be ventilated has to be included in air pollution control, other components used for air pollution control can be installed in the device in a separate air duct with its own fan.

EXAMPLE OF EXECUTION

The invention will be explained in more detail below on the basis of exemplary embodiments. The exemplary embodiments are intended to describe the invention without restricting it.

[0015] The invention is explained in more detail with reference to drawings. Show it

Fig. 1 Structure of the CO »filter cartridge

Fig. 2 CO »filter cartridge partial section with packing and filling

[0018] FIG. 3 CO »filter cartridge with an electrostatic fine dust separator placed in front

[0019] FIG. 4 CO »filter cartridge with electrostatic fine dust separator, fan and ozone element with residual ozone destroyer

Fig. 5 air circulation device CO »2 filter cartridge with fine dust separator, fan and ozone element in the duct installation

6 air circulation device with two separate air ducts, CO »filter cartridge with fine dust separator, fan and ozone element in the ventilation device

Figure 1 show the basic structure according to the invention of the CO »filter cassette (16) for bulk material as a CO2 sorption material. In this case, a chamber-shaped structure (19), FIG. 2, is present in the cassette frame (4) or is introduced subsequently in a tight manner (5), which takes up the bulk material (17). When filled, this chamber-shaped structure is sealed against dust discharge by a tightly applied filter mat (3) on the upstream and downstream sides. To ensure the stability of the filter mat and to protect it from damage, a firmly connected, air-permeable filter cover (2) closes the CO »filter off the inflow and outflow side. The material of the individual components is sodium hydroxide stable.

Fig. 3 shows the inventive combination of the CO> »- filter cartridge (16) with the upstream electrostatic dust separation unit (6, 7). In this case, the air flowing past is electrostatically charged negatively or, if necessary, positively via a spray electrode (12) or an ionization wire (13) or in the form of other discharge carriers. The ones charged with it

Particles or aerosols are attracted to the electrically conductive material in the following electrically conductive separator (6) due to the potential difference and are separated from the air. It is known that in particular fine dusts <10 μm can be separated from the air with up to 99%. This ensures that the active surface of the CO> »sorbent material in the CO» filter (16) remains almost free of deposits and that no so-called filter cake of dust is formed during the saturation time of the CO> »filter with CO» from the air forms.

4 shows a further advantageous combination of components according to the invention for operating the CO »filter with upstream electrostatic dust separation (6, 7). A suction fan (1) is attached on the outlet side to avoid back pressure in the air-conducting system. The CO> filter cassette (16), consisting of a filter frame (4) with a chamber-shaped structure (5), dust filter mats (2) and filter covers (3) is attached in front of the fan. The electrostatic fine dust separator (6,7) is located in front of the CO »filter cassette. Again in front of this is an ozone generation unit (8) which generates ozone from the air on the basis of dielectrically impeded discharge or UV. In this embodiment, the ozone generator unit (8) consists of a power unit (9) and an ozone generator (10) which generates an NTP and leads to germs, bacteria or organic loads such as e.g. VOC are oxidized and do not pollute the active surface of the CO »2 sorbent material. To destroy residual ozone, i.e. A sorption catalytic converter (22) is connected downstream of the ozone generator unit to break down unreacted ozone.

Fig. 5 shows an advantageous embodiment of the inventive combination of CO> filter cassette (16) and upstream electrostatic fine dust separator (6,7) in a circulating air device (20) for closed rooms. This combination is supplemented by an upstream ozone generator (8) and a suction fan (1) in the air flow direction. With this combination it is possible to treat room air contaminated with CO, dust, germs or odors and to release adequately clean outside air into the room. The sucked in air is first almost completely freed of germs and other organic pollution by the ozone formed after the ozone generator (8). Remaining fine dust is separated in the electrostatic separator (6,7), so that the air flow contaminated with CO »reaches the CO>» filter cassette, in which large parts of the CO »are bound. Even with larger CO »loads of> 5,000 ppm, only an air flow with a CO» saturation of max. 800 ppm off. All parts installed and shown in the air duct (14) can be exchanged and, with the exception of the combination according to the invention, CO> »filter cassette (16) and electrostatic separator (6, 7), can be installed in any order. The CO »filter cassette can be rotated so that the old outflow side can be used as the inflow side, which extends the service life.

Fig. 6 shows a further advantageous embodiment of the inventive combination of CO »filter cassette (16) and upstream electrostatic fine dust separator (6,7) in a circulating air device (20) for closed rooms. On the device side, this combination is supplemented by a further air-conducting duct with its own fan (1) and an ozone generator (8) connected upstream in the air direction with a downstream sorption catalyst (22). With this combination it is possible to treat room air contaminated with CO »2, dust, germs or odor and to release adequately clean outside air into the room. The sucked in air is first almost completely freed of germs and other organic pollution by the ozone formed after the ozone generator (8). Remaining fine dust is separated in the electrostatic separator (6,7), so that the air flow contaminated with CO »reaches the CO>» filter cassette, in which large parts of the CO »are bound. Even with larger CO »loads of> 5,000 ppm, only an air flow with a CO» saturation of max. 800 ppm off. All parts installed and shown in the air duct (14) can be exchanged and, with the exception of the combination according to the invention, CO> »filter cassette (16) and electrostatic separator (6, 7), can be installed in any order. The CO »filter cassette can be rotated so that the old outflow side can be used as the inflow side, which extends the service life. A CO »2 sensor with a display after the CO» filter is installed to control the reduction of CO2. To increase the air quality in the room

After the fan (1) for the CO »filter cassette (6, 7), there is an ionization module (7) without an electrical fine dust separator, which ionizes the air discharged into the room.

REFERENCE LIST

1. Fan 2. Filter cover

3. Dust filter mat

4. Filter frame

5. Filter holder

6. Electronic fine dust separator 7. Ionization module

8. Ozone module

9. Ozone generator power section 10. Ozone generator

11. Power unit fine dust separator 12. Spray electrode

13. Ionization wire

14. Air duct

15. Seal

16. CO> filter

17. CO »bulk goods

18. Filling chamber

19. Pre-filter

20. Room ventilation unit

21. Ionization wire

22. Sorption catalyst

Claims (10)

Expectations 1. CO »air filter for installation in ventilation ducts, primarily in circulating air devices based on soda lime, consisting of sodium hydroxide, calcium hydroxide, water and ethyl violet as CO» 2 sorption material, whereby the proportion of sodium hydroxide does not exceed 4%, characterized in that the CO »-absorbing material (17) in the form of bulk material in small, air-permeable chambers (18) in the filter frame or a fabric is introduced so that a settlement or compression over 2.5% is no longer possible, these chambers against the discharge of Dusts from the sorbent material into the air flow are sealed upstream and downstream by appropriately dimensioned filter mats (2,3) and an electrostatic fine dust separation unit (6,7,12,13) for separating fine dusts <10 µm is connected upstream of the CO> »filter cassette is. 2. CO »air filter according to claim 1, characterized in that the CO» filter cartridge is additionally stabilized by means of rigid filter covers (3). 3. CO »air filter according to claims 1-2, characterized in that the electrostatic fine dust separator (6,7,12) is designed as a so-called electrostatic precipitator with a spray electrode and a downstream electrically conductive separation unit (6). 4. CO »air filter according to claims 1-3, characterized in that the electrostatic fine dust separator is designed as an ionizer (11, 13) which electrostatically charges the air and the charged fine dusts are on the dust filter surface of the dust filter (3) of the CO> 2 Put the cassette down. 5. CO »air filter according to claims 1-4, characterized in that the electrical charge of the air by the electrical fine dust separator (7) is negative or positive. 6. CO »air filter according to claims 1-5, characterized in that the filter cassette (16) can be refilled. 7. CO »air filter according to claim 1-6, characterized in that an ozone generating unit (8,9,10) is arranged in front of the entire combination of CO» filter cartridge and electrical dust separator. 8. CO »air filter according to claims 1-7, characterized in that the CO>» air filter is installed in a room recirculation device (20). 9. CO »air filter according to claims 1-8, characterized in that the CO2 reduction function is made technically available by displaying the saturation of the CO>» filter or by displaying the difference in the CO> content before and after the CO »filter. 10. CO »air filter according to claims 1-9, characterized in that the CO>» - air filter (16,6,7) in the room air device with an independent fan separately from other ventilation components operated by another fan (1,22,8 , 19) is operated. In addition 6 sheets of drawings